JP6369782B2 - Power supply device, headlight device using the power supply device, and vehicle using the headlight device - Google Patents

Description

  The present invention relates to a power supply device, a headlight device using the power supply device, and a vehicle using the headlight device.

  2. Description of the Related Art Conventionally, a power supply device including a DC-DC converter controlled at a constant current is provided, and is used for lighting a light emitting diode in a headlamp device (see, for example, Patent Document 1). When the above power supply device is used for a headlamp device, an in-vehicle battery is used as a power source for the DC-DC converter.

JP 2011-113642 A

  When the power source of the DC-DC converter is an in-vehicle battery or the like and is also connected to another load (for example, a cell motor), the power source voltage (DC-DC converter) is operated during operation of the other load (for example, when the engine is started). May be temporarily reduced.

  While the power supply voltage is decreasing, the DC-DC converter is controlled to increase the output current in order to compensate for the decrease in output current due to the decrease in power supply voltage. Specifically, for example, when the DC-DC converter is a boost converter (step-up chopper) or a flyback converter, the on-duty of the switching element is increased.

  However, if the power supply voltage is restored after temporarily decreasing, the output current from the DC-DC converter to the load may increase excessively due to a control delay immediately after the power supply voltage is restored. It was.

  The present invention has been made in view of the above reasons, and an object thereof is to provide a power supply device in which an excessive increase in output current is unlikely to occur, a headlamp device using the power supply device, and the headlamp device. There is.

  The power supply device of the present invention includes a DC-DC converter configured to output DC power obtained by converting input power from an external DC power supply, a control circuit that controls the DC-DC converter, and the DC power supply. An input voltage detection circuit configured to detect an input voltage to the DC-DC converter, wherein the control circuit uses the input voltage detected by the input voltage detection circuit as a predetermined first threshold value and the input voltage. Compared with a predetermined second threshold value lower than the first threshold value, the output of the DC-DC converter is stopped when the duration of the state where the input voltage is below the first threshold value reaches a predetermined hold time And the output current of the DC-DC converter is reduced when the input voltage falls below the second threshold value.

  A headlamp device according to the present invention includes the power supply device described above and a light source that is turned on by output power of the power supply device.

  A vehicle according to the present invention includes the above-described headlight device and a vehicle body on which the headlight device is mounted.

  According to the present invention, an excessive increase in output current is unlikely to occur.

It is a circuit block diagram which shows an example of the power supply device which concerns on this invention. It is explanatory drawing which shows an example of the relationship between the primary side electric current I1 in the DC-DC converter of said power supply device, and the on-off state of switching element SW1. It is explanatory drawing which shows an example of operation | movement of the control circuit in said power supply device. It is explanatory drawing which shows an example of the time change of the input voltage Vi, the on-off state of switching element SW1, and the output current Io in said power supply device. It is explanatory drawing which shows another example of the time change of the input voltage Vi, the on-off state of switching element SW1, and the output current Io in said power supply device. FIG. 6 is an explanatory diagram showing an example of a time change of an input voltage Vi, an on / off state of a switching element SW1, an output current Io, and a current command value Ia in the power supply device. It is explanatory drawing which shows another example of the time change of the input voltage Vi, the on-off state of switching element SW1, and the output current Io in said power supply device. It is a circuit block diagram which shows another example of said power supply device. It is explanatory drawing which shows another example of operation | movement of the control circuit in said power supply device. It is a circuit block diagram which shows another example of said power supply device. It is explanatory drawing which shows an example of the headlamp apparatus using said power supply device. It is explanatory drawing which shows an example of the vehicle using said power supply device.

  As shown in FIG. 1, a power supply device 1 of the present invention includes a DC-DC converter 2 configured to output DC power obtained by converting input power from an external DC power supply 51, and a DC-DC converter 2. And a control circuit 3 for controlling. The power supply device 1 also includes an input voltage detection circuit VD1 configured to detect an input voltage from the DC power supply 51 to the DC-DC converter 2. The control circuit 3 compares the input voltage Vi detected by the input voltage detection circuit VD1 with a predetermined first threshold value Vth1 lower than the rated voltage of the DC power supply 51 and a predetermined second threshold value Vth2 lower than the first threshold value Vth1. To do. Then, the control circuit 3 stops the output of the DC-DC converter 2 when the continuation time Tx1 in a state where the input voltage Vi is lower than the first threshold value Vth1 reaches a predetermined holding time Tth1. In addition, when the input voltage Vi falls below the second threshold value Vth2, the control circuit 3 decreases the output current Io of the DC-DC converter 2.

  In the power supply device 1 described above, the control circuit 3 compares the input voltage Vi detected by the input voltage detection circuit VD1 with a predetermined third threshold value Vth3 when the output of the DC-DC converter 2 is stopped. May be. The third threshold value Vth3 is lower than the rated voltage of the DC power supply 51 and higher than the first threshold value Vth1. In this case, it is desirable that the control circuit 3 does not start the DC-DC converter 2 in a state where the input voltage Vi is lower than the third threshold value Vth3.

  In the power supply device 1 described above, the DC-DC converter 2 may include a switching element SW1 that is driven on and off by the control circuit 3, an inductor (transformer T), and a capacitor C1. In the inductor (transformer T), energy is accumulated by power supply from the DC power source 51 during the ON period in which the switching element SW1 is ON. The capacitor C1 is charged by the regenerative current from the inductor (transformer T) during the period when the switching element SW1 is turned off. In this case, when the input voltage Vi falls below the second threshold value Vth2, the control circuit 3 may decrease the upper limit value of the length of the on period.

  In the power supply device 1 described above, the DC-DC converter 2 may include a switching element SW1 that is driven on and off by the control circuit 3, an inductor (transformer T), and a capacitor C1. In the inductor (transformer T), energy is accumulated by power supply from the DC power source 51 during the ON period in which the switching element SW1 is ON. The capacitor C1 is charged by the regenerative current from the inductor (transformer T) during the period when the switching element SW1 is turned off. In this case, in the state where the input voltage Vi is lower than the second threshold value Vth2, the control circuit 3 causes the switching element SW1 to stop after the regenerative current stops compared to the state where the input voltage Vi is equal to or higher than the second threshold value Vth2. Increase the delay time until the is turned on.

  Alternatively, in the power supply device 1 described above, the control circuit 3 may set the output current Io of the DC-DC converter 2 to 0 when the input voltage Vi falls below the second threshold value Vth2.

  In the power supply device 1 described above, the control circuit 3 sets the input voltage Vi detected by the input voltage detection circuit VD1 to a predetermined fourth threshold Vth4 that is lower than the rated voltage of the DC power supply 51 and higher than the first threshold Vth1. You may compare. In this case, the control circuit 3 outputs the output of the DC-DC converter 2 when the duration of the state where the input voltage Vi is lower than the fourth threshold value Vth4 reaches a predetermined second hold time Tth2 longer than the hold time Tth1. Stop.

  The headlamp device 6 according to the present invention includes any one of the power supply devices 1 described above and the light source 4 that is turned on by the output power of the power supply device 1.

  A vehicle 5 according to the present invention includes the above-described headlamp device 6 and a vehicle body 50 on which the headlamp device 6 is mounted.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

  As shown in FIG. 1, the power supply device 1 of this embodiment includes a DC-DC converter 2 configured to output DC power obtained by converting input power from an external DC power supply 51, and a DC-DC converter 2. And a control circuit 3 configured to control the above. The output of the DC-DC converter 2 is used for lighting a light source 4 in which a plurality of light emitting diodes 41 are connected in series. The power supply device 1 also includes a control power supply circuit 11 that converts DC power input from the DC power supply 51 to generate a power supply for the control circuit 3. The control power supply circuit 11 is composed of, for example, a known three-terminal regulator.

  The DC power source 51 is composed of, for example, an in-vehicle battery. In addition, a switch 52 that turns on / off the power supply from the DC power supply 51 to the power supply device 1 is provided between the DC power supply 51 and the power supply device 1.

  The DC-DC converter 2 is a so-called flyback converter, and includes a transformer T as an inductor and a switching element SW1 connected to a DC power source 51 as a series circuit of a primary winding of the transformer T. A series circuit of a diode D1 and a capacitor C1 is connected to the secondary winding of the transformer T, and the voltage across the capacitor C1 is the output voltage of the DC-DC converter 2. The diode D1 is connected in such a direction that a charging current flows from the secondary winding of the transformer T to the capacitor C1 when the current input from the DC power source 51 to the primary winding of the transformer T decreases. For example, an n-channel MOSFET is used as the switching element SW1.

  That is, during the period when the switching element SW1 is turned on, energy is accumulated in the core of the transformer T, and the current flowing through the primary winding of the transformer T gradually increases. Further, during the period when the switching element SW1 is turned off, the above energy is released from the secondary winding of the transformer T, and the capacitor C1 is charged by the regenerative current flowing through the diode D1, while the transformer T The voltage across the primary winding gradually decreases.

  Further, the power supply device 1 includes an RS flip-flop circuit FF having a Q terminal connected to the gate of the switching element SW1. That is, the switching element SW1 is driven by the output of the flip-flop circuit FF.

  Further, the power supply apparatus 1 outputs a voltage obtained by differentiating the drain-source voltage of the switching element SW1 (that is, a voltage obtained by combining the voltage of the DC power supply 51 and the voltage across the primary winding of the transformer T). Is provided. The output of the differentiation circuit DV is input to the S terminal of the flip-flop circuit FF via the timing control unit 30 of the control circuit 3 and the first OR circuit OR1. The timing control unit 30 inputs a pulse to the S terminal of the flip-flop circuit FF via the first OR circuit OR1 after a delay time has elapsed since the pulse was input from the differentiation circuit DV. The delay time is normally 0. In this case, the switching element SW1 is turned on at the timing when the regenerative current in the secondary winding of the transformer T stops.

  The power supply device 1 further includes a primary side current detection circuit CD1 that detects a current flowing through the switching element SW1 (hereinafter referred to as “primary side current I1”). Furthermore, the power supply device 1 includes a comparator CP that compares the primary current I1 detected by the primary current detection circuit CD1 with the primary current command value Ic input from the control circuit 3. The output of the comparator CP is input to the R terminal of the flip-flop circuit FF via the second OR circuit OR2.

  That is, as shown in FIG. 2, the primary-side current I1 gradually increases during a period in which the switching element SW1 is on (hereinafter referred to as “on period”). When the primary side current I1 reaches the primary side current command value Ic, the output of the comparator CP becomes H level, so that a pulse is input to the R terminal of the flip-flop circuit FF and the switching element SW1 is turned off. .

  Further, during the period in which the switching element SW1 is off (hereinafter referred to as “off period”), the capacitor C1 is charged by the regenerative current flowing in the secondary winding of the transformer T, and the primary winding of the transformer T The voltage at both ends gradually decreases. When the voltage across the primary winding of the transformer T eventually drops (that is, the regenerative current stops), the pulse output from the differentiation circuit DV is input to the S terminal of the flip-flop circuit FF via the timing control unit 30. As a result, the switching element SW1 is turned on. Thereafter, the above operation is repeated. When the delay time in the timing control unit 30 is set to 0, the operation of the DC-DC converter 2 is a so-called current critical mode (BCM).

  That is, as the primary current command value Ic input to the comparator CP by the control circuit 3 is higher, the duty ratio of the switching element SW1 is higher and the output current Io of the DC-DC converter 2 is increased.

  Further, voltage dividing resistors R 1 and R 2 are connected between the output terminals of the DC-DC converter 2. The power supply device 1 is electrically connected to a connection point of the voltage dividing resistors R1 and R2, and outputs an output voltage detection circuit VD2 that detects an output voltage (hereinafter simply referred to as “output voltage”) Vo of the DC-DC converter 2. Is provided. Specifically, the output voltage detection circuit VD2 is a circuit that performs appropriate conversion (for example, A / D conversion) on the voltage divided by the voltage dividing resistors R1 and R2 and inputs the voltage to the control circuit 3, for example. Further, the control circuit 3 calculates the average value of the output voltage Vo detected by the output voltage detection circuit VD2 and the average value for the most recent predetermined time (hereinafter referred to as “average output voltage”) E (Vo). An average output voltage calculation unit 31 is provided.

  Further, a resistor R3 made of, for example, a shunt resistor is connected between the output terminal on the low potential side of the DC-DC converter 2 and the output terminal on the low potential side of the power supply device 1. The power supply device 1 includes an output current detection circuit CD2 that detects an output current (hereinafter simply referred to as “output current”) Io of the DC-DC converter 2 based on the voltage across the resistor R3. Specifically, the output current detection circuit CD2 is, for example, a circuit that performs appropriate conversion (for example, A / D conversion) on the voltage across R3 and inputs it to the control circuit 3. The control circuit 3 calculates the average value of the output current Io detected by the output current detection circuit CD2 and the average value for the most recent predetermined time (hereinafter referred to as “average output current”) E (Io). An average output current calculator 32 is included.

  Further, the control circuit 3 outputs a target output unit 33 that outputs a target value of the output current Io (hereinafter referred to as “current command value”), and a primary side corresponding to the current command value Ia output by the target output unit 33. And a comparison calculation unit 34 that calculates the current command value Ic and outputs the current command value Ic to the comparator CP. The comparison calculation unit 34 outputs a primary side current command value Ic that brings the average output current E (Io) output from the average output current calculation unit 32 close to the current command value Ia output from the target output unit 33. Specifically, if the average output current E (Io) is lower than the current command value Ia, the primary side current command value Ic is increased, and conversely, the average output current E (Io) is higher than the current command value Ia. For example, the primary side current command value Ic is lowered. This achieves feedback control (so-called constant current control) that brings the output current Io closer to the current command value Ia. If the average output voltage E (Vo) output from the average output voltage calculation unit 31 is used by the target output unit 33 for calculating the current command value Ia, the output power of the DC-DC converter 2 is kept constant. Such feedback control (so-called constant power control) is also possible.

  In addition, the control circuit 3 includes an on-time measuring unit 35 that measures the length of the on-period (that is, the duration of the on-state of the switching element SW1; hereinafter referred to as “on-time”). The on-time measuring unit 35 forces the switching element SW1 by inputting a pulse to the R terminal of the flip-flop circuit FF via the second OR circuit OR2 when the on-time reaches a predetermined upper limit on-time. Turn off. Thereby, for example, even when an abnormality occurs in the primary side current detection circuit CD1, it is possible to avoid an excessive increase in the primary side current I1. The upper limit on time may be a fixed value or may be calculated using the output voltage Vo, the output current Io, or the input voltage Vi. The upper limit on time Ton determined by the calculation is, for example, the output voltage Vo, the output current Io, the circuit efficiency η of the DC-DC converter 2, the turn ratio n of the transformer T, and the primary winding of the transformer T. Using the inductance L, for example, the value is as follows. Strictly speaking, average values E (Vo), E (Io), and E (Vi) are used as the output voltage Vo, the output current Io, and the input voltage Vi, respectively. The on-time measuring unit 35 stores an upper limit value and a lower limit value of the upper limit on time Ton. When the upper limit on time Ton obtained as a result of the calculation is equal to or greater than the upper limit value, the upper limit value is used as the upper limit on time Ton, and the upper limit on time Ton obtained as a result of the calculation is less than the lower limit value. In this case, the above lower limit value is used as the upper limit on time Ton.

  In addition, the control circuit 3 includes an off-time measuring unit 36 that measures the length of the off-period (that is, the duration time of the switching element SW1 in the off state, hereinafter referred to as “off time”). The off-time measuring unit 36 forces the switching element SW1 by inputting a pulse to the S terminal of the flip-flop circuit FF via the first OR circuit OR1 when the off-time reaches a predetermined upper limit off-time. Turn it on. Thereby, for example, even when an abnormality occurs in the differentiation circuit DV, it is possible to avoid the output from being stopped. Further, the frequency of noise generated with the driving of the switching element SW1 can be kept high to some extent.

  The power supply device 1 also includes a circuit temperature detection circuit 12 that detects the temperature of circuit components of the power supply device 1 and a light source temperature detection circuit 13 that detects the temperature of the light source 4. The circuit temperature detection circuit 12 is disposed close to a circuit component (for example, the switching element SW1) that generates a relatively large amount of heat. In addition, the light source temperature detection circuit 13 is disposed close to the light source 4. Each of the circuit temperature detection circuit 12 and the light source temperature detection circuit 13 can be realized by a known technique using, for example, a thermistor.

  The target output unit 33 of the control circuit 3 lowers the current command value Ia as the temperature detected by the circuit temperature detection circuit 12 or the light source temperature detection circuit 13 is higher. Thereby, the heat_generation | fever in the circuit component of the power supply device 1 and the light source 4 is suppressed.

  Furthermore, the power supply device 1 includes an input voltage detection circuit VD1 that detects an input voltage Vi from the DC power supply 51 to the DC-DC converter 2. The input voltage detection circuit VD1 can be realized by a known technique using, for example, a voltage dividing resistor.

  Further, the control circuit 3 includes an input voltage determination unit 37 that determines whether or not the input voltage Vi detected by the input voltage detection circuit VD1 is decreasing. The input voltage determination unit 37 reads the input voltage Vi from the input voltage detection circuit VD1 every predetermined time, and stores it for a predetermined number of times (for example, four times) from a new one. Then, every time the input voltage Vi is obtained from the input voltage detection circuit VD1, the input voltage determination unit 37 calculates the average input voltage E (Vi) that is the average value for the predetermined number of times, and this average input voltage E (Vi ) And the instantaneous value Vi are used for the determination.

  Hereinafter, the operation of the control circuit 3 will be described with reference to FIG.

  When the switch 52 is turned on and the power supply from the DC power source 51 is started (F01), the control circuit 3 first performs an initialization process for returning the parameters used for the operation to the initial values (F02). Next, the input voltage determination unit 37 of the control circuit 3 obtains the input voltage Vi from the input voltage detection circuit VD1 (F03), and calculates the average input voltage E (Vi) if the input voltage Vi for a predetermined number of times is obtained. (F04). Further, the input voltage determination unit 37 of the control circuit 3 compares the average input voltage E (Vi) with a predetermined third threshold Vth3 (for example, 9V) lower than the rated voltage (for example, 12V) of the DC power supply 51 (F05). ). If the average input voltage E (Vi) is equal to or higher than the third threshold value Vth3 (Y in F05), for example, the timing control unit 30 outputs a pulse to the first OR circuit OR1, thereby driving the switching element SW1. Started (F06). On the other hand, if the average input voltage E (Vi) is less than the third threshold value Vth3 (N in F05), the process returns to Step F03 without starting the driving of the switching element SW1.

  After the driving of the switching element SW1 is started, the input voltage determination unit 37 again obtains the input voltage Vi from the input voltage detection circuit VD1 (F07), and a predetermined second threshold value lower than the third threshold value Vth3. Compare with Vth2 (for example, 4.5V) (F08). When the input voltage Vi is lower than the second threshold value Vth2 (N in F08), the control circuit 3 performs an output reduction operation for reducing the output current (F09).

  When the input voltage Vi is equal to or greater than the second threshold Vth2 (Y in F08), the input voltage determination unit 37 of the control circuit 3 calculates the average input voltage E (Vi) (F10). Further, the input voltage determination unit 37 of the control circuit 3 compares the average input voltage E (Vi) with a predetermined first threshold value Vth1 that is lower than the third threshold value Vth3 and higher than the second threshold value Vth2 (F11). When the input voltage Vi is lower than the first threshold value Vth1 (N in F11), the control circuit 3 adds the first count Tx1 (F12), and compares the first count Tx1 with a predetermined holding time Tth1. (F13). When the first count Tx1 (that is, the duration in which the input voltage Vi is lower than the first threshold Vth1) has reached the holding time Tth1 (Y in F13), the control circuit 3 drives the switching element SW1. Is stopped (F14), and the process returns to step F03. That is, in step F14, both the operation of the timing control unit 30 and the operation of the off-time measuring unit 36 are stopped, and the output of the DC-DC converter 2 is stopped by maintaining the switching element SW1 in the off state. . The first threshold value Vth1 is set to 6 V, for example, and the holding time Tth1 is set to 60 ms, for example, so that the step F14 is stopped when the input voltage Vi is reduced by the cell motor operation at the time of engine start.

  After the control circuit 3 stops driving the switching element SW1 in step F14 and returns to step F03, the driving of the switching element SW1 is not resumed until the average input voltage E (Vi) becomes equal to or higher than the third threshold value Vth3. Here, when the third threshold value Vth3 is equal to the first threshold value Vth1, when the input voltage Vi vibrates in the vicinity of the first threshold value Vth1, the driving and stopping of the switching element SW1 are repeated, and the light source 4 blinks. In the present embodiment, since the third threshold value Vth3 is higher than the first threshold value Vth1, even when the input voltage Vi oscillates as described above, the switching element SW1 is repeatedly driven and stopped as described above. And the light source 4 is less likely to blink.

  On the other hand, when the input voltage Vi is equal to or higher than the first threshold value Vth1 (Y in F11), the control circuit 3 resets the first count Tx1 (F15). Thereafter, the process proceeds to step F13, but the process proceeds to the next step F16 when the first count Tx1 naturally falls below the holding time Tth1.

  Further, when the input voltage Vi is lower than the first threshold value Vth1 (N in F11) and the first count Tx1 has not reached the holding time Tth1 (N in F13), the first count Tx1 is reset. Instead, the process proceeds to the next step F16.

  In the next step F16, feedback control by the operations of the target output unit 33 and the comparison calculation unit 34 is achieved. Further, in step F16, it may be determined whether or not an abnormality has occurred, or the driving of the switching element SW1 when it is determined that there is an abnormality (transition to step F14) may be performed. As an abnormality, for example, a power supply abnormality that is determined to occur when the input voltage Vi is excessively high, a short-circuit state that is determined to occur when the output current Io is excessively large, or a case where the output voltage Vo is excessively high A no-load state (open state) in which occurrence is determined at the time may be considered. In step F16, even when the average input voltage E (Vi) is higher than the rated voltage (for example, 12V), or when the current command value Ia is low to some extent, the delay time in the timing control unit 30 is made larger than zero. Good. After the operation of step F16 is completed, the control circuit 3 returns to step F07.

  Here, in the output reduction operation in step F09, for example, the upper limit on-time is made shorter than usual. In this case, the time change of the input voltage Vi, the on / off state of the switching element SW1, and the output current Io is, for example, as shown in FIG. The upper limit on time during the output reduction operation may be a fixed value, or may be a time obtained by subtracting a predetermined value from the upper limit on time in the normal time.

  Further, during the output decreasing operation, the delay time in the timing control unit 30 may be set longer than the delay time during the period in which the input voltage Vi exceeds the second threshold value Vth2. That is, in the output reduction operation described above, the control circuit 3 delays the timing for turning on the switching element SW1 with respect to the timing at which the regenerative current stops in the secondary winding of the transformer T. That is, the operation of the DC-DC converter 2 during the output reduction operation is a so-called current discontinuous mode (DCM).

  In this case, the time change of the input voltage Vi, the on / off state of the switching element SW1, and the output current Io is, for example, as shown in FIG.

  In the output reduction operation, the target output unit 33 sets the current command value Ia input to the comparison calculation unit 34 to be lower than normal (that is, a period in which the input voltage Vi is equal to or greater than the second threshold Vth2) (for example, to 0). ) In this case, the time change of the input voltage Vi, the on / off state of the switching element SW1, the output current Io, and the current command value Ia is as shown in FIG. 6, for example. In the example of FIG. 6, since the timing at which the primary side current command value Ic is updated is delayed with respect to the timing at which the current command value Ia decreases, the decrease in the current command value Ia is reflected in the operation of the switching element SW1. There is a time lag before it is done. In the example of FIG. 6, the control circuit 3 gradually increases the current command value Ia after returning until the input voltage Vi becomes equal to or higher than the second threshold value Vth2. The same effect can be obtained even when the comparison calculation unit 34 lowers the primary current command value Ic instead of the target output unit 33 lowering the current command value Ia as described above.

  Among the various output reduction operations, the output reduction operation that delays the ON timing of the switching element SW1 and the output reduction operation that lowers the current command value Ia and the primary current command value Ic are the on-time measuring unit 35 and the second one. This can be realized even when one OR circuit OR1 is not provided.

  Further, a plurality of the various output reduction operations may be combined. For example, in the output reduction operation, the upper limit on time may be shortened and the delay time may be lengthened.

  Alternatively, when the input voltage Vi is lower than the second threshold value Vth2 (N in F08), the output current Io may be reduced to 0 by proceeding to Step F14 and stopping the driving of the switching element SW1. . In this case, the time change of the input voltage Vi, the on / off state of the switching element SW1, and the output current Io is, for example, as shown in FIG.

  According to the above configuration, since the output current Io is reduced if the input voltage Vi is lower than the second threshold value Vth2, even if the input voltage Vi returns after being lower than the second threshold value Vth2, the output due to the control delay An excessive increase in current Io is unlikely to occur.

  Also, since the instantaneous value Vi of the input voltage is used for comparison with the second threshold value Vth2, the input voltage Vi is different from the case where the average value E (Vi) of the input voltage is used for comparison with the second threshold value Vth2. The output current Io is also reduced with respect to a momentary drop of.

  Note that the DC-DC converter 2 is not limited to the flyback converter as described above, and may be, for example, a boost converter as shown in FIG. In the example of FIG. 8, a so-called autotransformer is used as the transformer T. The so-called autotransformer includes a single winding and the primary winding also serves as a part of the secondary winding.

  Further, as in steps F17 to F20 of FIG. 9, a predetermined fourth threshold Vth4 (for example, 7V) higher than the first threshold Vth1, and a predetermined second holding time Tth2 (for example, 150 ms) longer than the holding time Tth1. A determination using may be added. More specifically, in step F17, the input voltage determination unit 37 of the control circuit 3 compares the average input voltage E (Vi) with a predetermined fourth threshold Vth4 that is higher than the first threshold Vth1. When the input voltage Vi is lower than the fourth threshold value Vth4 (N in F17), the control circuit 3 adds the second count Tx2 (F18), and sets the second count Tx2 to a predetermined time longer than the holding time Tth1. Compare with the second holding time Tth2 (F19). When the second count Tx2 (that is, the duration of the state in which the input voltage Vi is lower than the fourth threshold value Vth4) has reached the second holding time Tth2 (Y in F19), the control circuit 3 uses the switching element SW1. Is stopped (F14). If the second count Tx2 has not reached the second holding time Tth2 (N in F19), the process proceeds to the next step F16. On the other hand, when the input voltage Vi is equal to or higher than the fourth threshold value Vth4 (Y in F17), the control circuit 3 resets the second count Tx2 (F20), and proceeds to the next step F16 through step F19. If an operation such as the above steps F17 to F20 is added, an excessive increase in the output current Io when the input voltage Vi returns after the input voltage Vi decreases is further less likely to occur.

  Note that the order of the determination F11 using the first threshold Vth1, the determination F08 using the second threshold Vth2, and the determination F17 using the fourth threshold Vth4 is not limited to the order shown in FIG. For example, the determination F08 using the second threshold Vth2 and the output reduction operation F09 corresponding to the determination result may be performed after the determination F11 using the first threshold Vth1. Alternatively, the timing at which the various determinations F11, F08, and F17 are performed may be determined by a timer interrupt.

  Further, the switching element SW1 may be turned off until the off time reaches the lower limit off time. Specifically, for example, as shown in FIG. 10, an AND circuit AND is provided between the S terminal of the flip-flop circuit FF and the first OR circuit OR1. The output terminal of the first OR circuit OR1 is connected to one input terminal of the AND circuit AND, and the off-time measuring unit 36 is connected to the other input terminal of the AND circuit AND. The off-time measuring unit 36 sets the input to the AND circuit AND to the L level during the period from when the switching element SW1 is turned off until the lower limit off time elapses, and to the H level during the other periods. In this case, the off-time measuring unit 36 may extend the above-described lower limit off-time during normal output reduction (that is, a period during which the input voltage Vi is equal to or greater than the second threshold value Vth2).

  The various power supply devices 1 can be used for a headlamp device 6 as shown in FIG. 11, for example. The headlamp device 6 of FIG. 11 includes a power supply device 1, a light source 4, and a housing 60 that houses the light emitting diodes 41 that constitute the light source 4 and holds the power supply device 1. Each light emitting diode 41 is fixed to a single substrate 61 in the housing 60. Each substrate 61 is fixed with a lens 62 that distributes the light of the light emitting diode 41 in a common direction (right direction in FIG. 11). Further, a part (the lower two in FIG. 11) of the light emitting diodes 41 are mounted with an arrangement and an orientation in which the optical axis coincides with the optical axis of the lens 62, and the other (the upper three in FIG. 11). 41 is mounted in a direction in which the optical axis intersects the optical axis of the lens 62. On each substrate 61 on which the light emitting diode 41 is mounted in a direction that intersects the optical axis of the lens 62, a reflecting plate 63 that reflects the light of the light emitting diode 41 toward the lens 62 is fixed. Further, in the housing 60, the wall on the side from which each light emitting diode 41 emits light (the right side in FIG. 11) is made of a light-transmitting material (for example, polycarbonate). The power supply device 1 is electrically connected to the DC power supply 51 and the switch 52 through a pair of electric wires 64. Since the headlamp device 6 as described above can be realized by a well-known technique, detailed description thereof is omitted. In addition, each circuit component which comprises the power supply device 1 may be accommodated in the housing 60, and one part or all part may be accommodated in a case separate from the said housing 60. FIG.

  The headlamp device 6 as described above can be used for a vehicle 5 including a vehicle body 50 on which the headlamp device 6 is mounted, for example, as shown in FIG. In the vehicle 5 of FIG. 12, the power supply to the two headlamp devices 6 is collectively turned on / off by one switch 52.

  As the light source 4, instead of the light emitting diode 41, other known electric light sources such as an organic EL may be used.

DESCRIPTION OF SYMBOLS 1 Power supply device 2 DC-DC converter 3 Control circuit 4 Light source 5 Vehicle 6 Headlamp device 50 Car body 51 DC power supply C1 Capacitor SW1 Switching element T Transformer (Inductor)
VD1 input voltage detection circuit

Claims (8)

A DC-DC converter configured to output DC power obtained by converting input power from an external DC power supply;
A control circuit for controlling the DC-DC converter;
An input voltage detection circuit configured to detect an input voltage from the DC power source to the DC-DC converter;
The control circuit compares the input voltage detected by the input voltage detection circuit with a predetermined first threshold value lower than a rated voltage of the DC power supply and a predetermined second threshold value lower than the first threshold value, and The output of the DC-DC converter is stopped when the duration of the state where the input voltage is below the first threshold reaches a predetermined holding time, and when the input voltage falls below the second threshold, the output is stopped. A power supply apparatus that reduces an output current of a DC-DC converter.   In a state where the output of the DC-DC converter is stopped, the control circuit causes the input voltage detected by the input voltage detection circuit to be lower than the rated voltage of the DC power supply and higher than the first threshold value. 2. The power supply device according to claim 1, wherein the DC-DC converter is not started in a state where the input voltage falls below the third threshold value as compared with a predetermined third threshold value. The DC-DC converter includes a switching element that is driven on and off by the control circuit, an inductor that stores energy by power supply from the DC power source during an on period in which the switching element is on, and the switching element is off. And a capacitor charged by a regenerative current from the inductor during a period of time,
3. The power supply device according to claim 1, wherein when the input voltage falls below the second threshold, the control circuit decreases an upper limit value of a length of the on period. The DC-DC converter includes a switching element that is driven on and off by the control circuit, an inductor that stores energy by power supply from the DC power source during an on period in which the switching element is on, and the switching element is off. And a capacitor charged by a regenerative current from the inductor during a period of time,
In the state where the input voltage is lower than the second threshold, the control circuit waits until the switching element is turned on after the regenerative current stops than in the state where the input voltage is equal to or higher than the second threshold. The power supply device according to claim 1, wherein the delay time is increased.   3. The power supply device according to claim 1, wherein the control circuit sets the output current of the DC-DC converter to 0 when the input voltage falls below the second threshold value. 4.   The control circuit compares the input voltage detected by the input voltage detection circuit with a predetermined fourth threshold value lower than a rated voltage of the DC power source and higher than the first threshold value, and the input voltage is the first voltage value. 6. The output of the DC-DC converter is stopped when a predetermined second holding time that is longer than the holding time has reached a duration that is below four thresholds. The power supply device according to claim 1. The power supply device according to any one of claims 1 to 6,
A headlamp device comprising: a light source that is turned on by output power of the power supply device.   A vehicle comprising: the headlamp device according to claim 7; and a vehicle body on which the headlamp device is mounted.

Images